DE3537920C2 - Stabilizer with protection against transient overvoltages, the polarity of which is opposite to the polarity of the generator, in particular for use in motor vehicles - Google Patents

Description

A stabilizer is placed between the genes rator and the load switched from the other electronics devices of the vehicle consists of a supplier to obtain DC voltage which is independent of that of is the current consumed.

A stabilizer must absorb all electrical loads, who adjust at his entrance, and must at his Suppress exit. In particular, he must protect and to protect the load the dangerous positive and negative Surges record in the electrical scarf result of the motor vehicle. A strong, negative chip voltage impulse is, for example, when the collapse alternating field (field breakdown or "field decay ") generated when the main switch of the circuit (Ignition key) is opened while the inductive loads (Alternator field windings, ignition, electrical Motors) are connected to the stabilizer. An electronic shear stabilizer would have the high, negative overvoltages record by acting like an open switch.

For applications where a relatively high output current is required, an electronic stabilizer is used, the power output stage of which consists of a bipolar PNP power transistor. This stabilizer has a high supply efficiency because the relative minimum voltage drop from input to output ("drop-out" or drop voltage) is equal to the collector-emitter saturation _voltage (V _CESAT ) of the PNP transistor, which is the current state of the art is the minimum achievable drop voltage.

The PNP transistor used as an output stage can be a lateral PNP transistor or a vertical PNP transistor with an insulated collector. The latter has a greater current density than the former and a higher current gain, so that its use is advantageous because it takes up a smaller silicon area and gives off a higher current at the output of the stabilizer. However, a vertical PNP transistor with an insulated collector has a reverse breakdown voltage of the base-emitter junction (V _EBO ), which is considerably lower than that of a lateral PNP transistor, which is why it is unable to absorb high negative overvoltages, because it behaves as an open switch. These overvoltages cause the breakdown of its base-emitter junction.

In the case of electronic stabilizers, the power level of which is made from egg a vertical PNP transistor with an insulated collector, is used to avoid destruction of the transistor at strong negative overvoltages are usually protective devices installed, of which he still has an embodiment is refined and limits the overvoltages mentioned. The However, this protective device takes up a very large area, which is comparable to the area of which the PNP power transistor needed, so their cost is relatively large are and it is economically unfavorable to have one in tegrated circuit both the power components, d. H. the PNP transistor and its protective device, as well as the rest components of the stabilizer.  

From the document DE 27 15 330 A1 is a protective circuit for known a voltage regulator, in which in the ground lead of Regulator a resistor is provided. Between the controller side End of the resistor and the controller input is a diode, preferably arranged a zener diode. When an occurring This becomes overvoltage via the Zener diode and the resistor derived.

A protective circuit is known from US-PS 35 71 608, a PNP transistor in the regulator's ground lead has with its emitter to ground and with its collector the input of the controller is connected. The base of this transistor is through a zener diode and a resistor to the input terminal the circuit switched.

The invention has for its object an electronic To create voltage stabilizer, the power amplifier from one vertical PNP transistor with insulated collector, which is a Protective device against negative overvoltages, which a much smaller area than the usual Protective devices so that it is economically more advantageous.  

This task is carried out by the Claim 1 feature solved.

Advantageous further developments are the subject of the dependent claims che.

The invention is he in one embodiment refines, which is shown in the drawing.

Show it:

Fig. 1 is a simplified circuit diagram of a voltage stabilizer with a known protection against negative over voltages and

Fig. 2 is a simplified circuit diagram of a voltage stabilizer with protection against negative overvoltages according to the invention.

In the two figures, diesel is used for matching parts ben reference numerals used.

The circuit shown in FIG. 1 has an input connection IN for connection to a generator which supplies a voltage which is positive with respect to ground, an output connection OUT for connection to a load and a connection common to the input and the output for connection to ground.

The circuit has a power end device, which consists of a bipolar power transistor T1, which is designed as a vertical PNP transistor with an insulated collector and whose emitter is connected to the input terminal IN, while its collector is connected to the output terminal OUT. The transistor T1 is controlled at its base by a control stage R. This control level is formed in a known manner and is therefore not shown. Usually, it consists of a differential amplifier that controls a bipolar NPN transistor, which in turn can control the bipolar PNP power transistor; This is illustrated, for example, in FIG. 3 on page 444 of the article by P. Menniti and S. Storti with the title "Low Drop Regulator with Overvoltage Protection and Reset Function for Automotive Environment", published in "IEEE Journal of Solid-State" Circu its ", volume SC-19, No. 3, June 1984, S, 442-448.

The control stage R has two input connections, one of which it ster inverting (-) and a second non-inverting (+) is an output connector and a connector for the connector dung with mass. The inverting connection is via a counter R1 stood at the output terminal OUT and through a resistor R2 connected to ground. The non-inverting input circuit is connected to a reference voltage VR. The exit connector is connected to the base of T1.

The circuit of FIG. 1 also has a power Zener diode Z1, a first power diode D1 and a second Lei stungsdiode D2 which are connected in series to each other. The anode of Z1 is connected to the input terminal IN, the cathodes of Z1 and D1 are connected to one another, the anode of D1 and the cathode of D2 are connected together to the output terminal OUT and the anode of D2 is connected to ground.

Between the output terminal OUT and ground lies in a known Instruct a voltage Vu whose magnitude is from the input voltage Vi and the load connected to the output terminal only so long depends on how the voltage Vi is smaller than a certain one Is threshold that is characteristic of the circuit and above which a DC voltage VO is established at the output, the size of both the input voltage Vi and the  Load is independent and only from the reference voltage VR and Dimensioning of the circuit depends, in particular on the ratio nis between the resistors R1 and R2. Above this smolder lenwert, which is the lower limit of the range of a correct Operation (and thus a possible use) of the stabilizer represents lisators, the control stage R namely stable. It compares the reference voltage VR with a fraction of the Output voltage Vu obtained by the voltage divider R1, R2 will; in the event of deviations in the output voltage from that predetermined value VO it controls the transistor T1 to a such a degree of conduction that a tension of the Size VO is restored.

During normal operation of the stabilizer, the trans is sistor T1 switched on, while the diode D1 in the reverse direction is biased so that the Zener diode Z1 is not in the lead the state is coming. The diode D2 is also under these conditions switched off.

Zener diode Z1 has an ignition voltage that is less than the reverse breakdown voltage of the base-emitter junction of T1, so that it protects T1 against negative overvoltages. This is because the transistor T1 is switched off during the transitions in which negative upper voltages occur, and when the voltage V _CE between its collector and its emitter becomes equal to the sum of the ignition voltage of Z1 and the threshold voltage of D1, these components come into the conductive state and discharge the energy associated with the transition, thereby preventing the overvoltages from adopting values that cause the breakdown of the base-emitter transition from T1. The diode D2 also comes into the conductive state, so that the discharge current flows through the diode D1 instead of through the load and the voltage divider R1, R2.

A protective device against negative overvoltages with the be written structure must absorb relatively high currents can, so that it takes up a very large area and thus is economically disadvantageous.

These problems are solved in the invention in that in A protective device is installed in the stabilizer that an ignition circuit, which the PNP transistor T1 in can control the inverse conductive state if the negati ve overvoltage reaches a predetermined value, the smaller than the value that represents the breakdown of the base-emitter over ganges caused by T1. The Ener appearing at the transition gie is discharged in this way through the same transistor T1, without the need for additional power components.

The circuit shown in Fig. 2 according to the invention has an ignition circuit consisting of a Zener diode Z2 and a PNP transistor T2. The anode of Z2 is connected to the input terminal IN of the stabilizer, while its cathode is connected to the base of T2. The collector of T2 is connected to the emitter of T1 and the emitter of T2 is connected to the base of T1.

Z2 and T2 are off during normal operation of the stabilizer switches.

For transitions in which negative tensions arise, transistor T1 remains off as long as the voltage between the cathode and the anode of Z2 smaller than the ignition is worth. The Zener diode switches above this value Z2 and controls the transistor T2 and thus also the Tran sistor T1 in the conductive state. The base-emitter junction of T1 is reverse biased while its base col Lector transition is biased in the forward direction, so that the Transistor works in the inverse line area.  

The ignition voltage of Z1 is determined such that the transistor T1 is switched on before its base-emitter voltage reaches the breakdown value V _EBO .

The transistors T2 and T1 are connected to each other so that they form a Darlington connection when T1 conducts in the reverse direction. As is known, a high current gain is obtained with such a connection, so that a relatively small current is used to control the base of T2. A current flows through the Zener diode Z2, the strength of which is negligible with respect to the strength of the current flowing through the components Z1 and D1 of FIG. 1. The transistor T2 only needs to take a smaller current than the components mentioned.

The protective device shown in Fig. 2 is of simple construction and requires, since it needs less power, a smaller area than the protective device shown in Fig. 1, so that it is cheaper and can be integrated with the other components of the sta bilizer .

In the embodiment of the invention shown in Fig. 2, the protective device against negative overvoltages only one Ze nerdiode, but it may have more, in series interconnected Zener diodes, depending on the ignition voltage that one wants to get th. In addition, further variants of the ignition circuit are possible without thereby departing from the inventive concept.

Claims (6)

1. Stabilizer with an input connection (IN) for connection to a generator that supplies a voltage of a first polarity with respect to a ground connection, with an output connection (OUT) for connection to a load and with one of the input and the output common connection for connection to the ground connection, comprising:
a control stage (R) with a first input connection (-), a second input connection (+) and an output connection,
Feedback means (R1, R2) connected to the output terminal (OUT) of the stabilizer and the first input terminal (-) of the control stage (R),
a power terminal (T1) having a first input terminal connected to the input terminal (IN) of the stabilizer, having a second input terminal connected to the output terminal (OUT) of the stabilizer, and having a control terminal connected to the output terminal the control stage (R) is connected,
a protective device against input overvoltages with a polarity opposite to the first polarity between the input connection and the control connection of the power terminal device,
characterized in that the protection means causes the power terminal to conduct in the opposite direction to normal operation when the input overvoltage reaches a predetermined value. Stabilizer according to claim 1, wherein the power end direction has a power transistor (T1), the base of which the control connection is connected and the work in the inverse range can when the device is directed opposite to Direction of conduction occurs during normal operation characterized in that the protective device is a Has semiconductor circuit device between the one gangsanschluß (IN) of the stabilizer and the control connection of the Power terminal is switched and in the conductive State arrives when the input overvoltages pass reach the agreed value. 3. Stabilizer according to claim 2, characterized in that the protective device has a transistor (T2), the Ba sis is connected to the semiconductor circuit device, its collector with the emitter and its emitter with the Ba sis of the power transistor (T1) are connected.   4. Stabilizer according to claim 2 or 3, characterized in that the semiconductor circuit device a Zener diode (Z2) or has series-connected zener diodes which are biased in the reverse direction when the input over adjust tensions. 5. Stabilizer according to one of claims 2 to 4, in which the Power transistor (T1) is a bipolar PNP transistor, the emitter the first and its collector the second form the end of the power terminal, thereby characterized in that the transistor (T2), which in protection is included, a bipolar PNP train sistor is. 6. Stabilizer according to one of the preceding claims, since characterized in that it can be integrated monolithically.